Systems for Additive Manufacturing Processes Incorporating Active Deposition

ABSTRACT

Systems and methods in accordance with embodiments of the invention implement additive manufacturing processes whereby the constituent material of an object to be fabricated is manipulated prior to, or during, the respective deposition process such that different portions of the deposited constituent material can be made to possess different material properties. In one embodiment, an additive manufacturing apparatus includes: a nozzle configured to accommodate the extrusion of a constituent material through it and deposit the constituent material onto a surface in accordance with an additive manufacturing process to build up an object to be fabricated; and a subassembly configured to manipulate the material properties of some portion of the constituent material such that different portions of the deposited constituent material can be made to possess different material properties; where the subassembly is configured to begin said manipulation prior to, or concurrently with, its deposition onto a surface.

CROSS-REFERENCE TO RELATED APPLICATIONS

The current application is a divisional of U.S. application Ser. No.14/321,046 filed Jul. 1, 2014, which claims priority to U.S. ProvisionalPatent Application No. 61/936,263, filed Feb. 5, 2014, the disclosuresof which are hereby incorporated by reference.

FIELD OF THE INVENTION

The present invention generally relates to additive manufacturingapparatuses and techniques for additive manufacturing.

BACKGROUND

‘Additive manufacturing,’ or ‘3D Printing,’ is a term that typicallydescribes a manufacturing process whereby a 3D model of an object to befabricated is provided to an apparatus (e.g. a 3D printer), which thenautonomously fabricates the object by gradually depositing, or otherwiseforming, the constituent material in the shape of the object to befabricated. For example, in many instances, successive layers ofmaterial that represent cross-sections of the object are deposited orotherwise formed; generally, the deposited layers of material fuse (orotherwise solidify) to form the final object. Because of their relativeversatility, additive manufacturing techniques have generated muchinterest.

SUMMARY OF THE INVENTION

Systems and methods in accordance with embodiments of the inventionimplement additive manufacturing processes whereby the constituentmaterial of an object to be fabricated is actively manipulated prior to,or during, the deposition process such that different portions of thedeposited constituent material can be made to possess different materialproperties. In one embodiment, an additive manufacturing apparatusincludes: a nozzle configured to accommodate the extrusion of aconstituent material through the nozzle and deposit the constituentmaterial onto a surface in accordance with an additive manufacturingprocess to build up an object to be fabricated; and at least onesubassembly configured to manipulate the material properties of at leastsome portion of the constituent material such that different portions ofthe deposited constituent material can be made to possess differentmaterial properties; where the at least one subassembly is configured tobegin the manipulation of the material properties of the at least someportion of the constituent material prior to, or concurrently with, itsdeposition onto a surface.

In another embodiment, the subassembly is configured to begin themanipulation of the material properties of the at least some portion ofthe constituent material after it is extruded through the nozzle.

In still another embodiment, the subassembly includes at least one of:an electromagnetic wave source configured to subject at least someportion of the constituent material to electromagnetic waves to beginthe manipulation of its material properties; a magnetizing sourceconfigured to begin the magnetization of the at least some portion ofthe constituent material; a source of gas configured to subject the atleast some portion of the constituent material to the gas that beginsthe manipulation of its material properties; a vibrating apparatusconfigured to vibrate the at least some portion of the constituentmaterial to thereby begin the manipulation of its material properties;and a heating source configured to heat the at least some portion of theconstituent material to thereby begin the manipulation of its materialproperties.

In yet another embodiment, the additive manufacturing apparatus furtherincludes a spatial-orientation mechanism configured to orient thesubassembly relative to the nozzle.

In still yet another embodiment, the subassembly includes at least oneelectromagnetic wave source.

In a further embodiment, the electromagnetic wave source is coupled tothe nozzle.

In a still further embodiment, the electromagnetic wave source isindependent of the nozzle, such that the nozzle can move independentlyof the electromagnetic wave source during the buildup of an object to befabricated.

In a yet further embodiment, the subassembly further includes fiberoptic cables configured to transmit electromagnetic waves generated bythe electromagnetic wave source to constituent material that is extrudedthrough the nozzle.

In a still yet further embodiment, the subassembly further includesoptics for focusing electromagnetic waves generated by theelectromagnetic wave source onto constituent material that is extrudedthrough the nozzle.

In another embodiment, the at least one subassembly is at least twosubassemblies.

In still another embodiment, the at least two subassemblies are disposedabout the perimeter of the nozzle, and each of the at least twosubassemblies is configured to begin the manipulation of the materialproperties in the same manner on different respective portions ofconstituent material that is extruded through the nozzle.

In yet another embodiment, each of the subassemblies is configured tobegin the manipulation of the material properties on constituentmaterial that is extruded through the nozzle in a manner differentlythan the other respective subassembly.

In still yet another embodiment, the nozzle is configured to accommodatethe extrusion of a constituent material that includes at least twocomponent materials, and the subassembly is configured to begin themanipulation of the material properties of at least some portion of theconstituent material by manipulating the composition of thecross-section of the constituent material as it is extruded through thenozzle.

In a further embodiment, the subassembly is configured to manipulate thespatial positioning of a first component material relative to a secondcomponent material within a given cross-section of the constituentmaterial as it is deposited on a surface.

In a still further embodiment, the subassembly includes a channel thatis configured to transmit the first component material for aggregationwith the second component material to form the constituent material.

In a yet further embodiment, the subassembly is configured to cause theaggregation of the first component material and the second componentmaterial prior to, or at the time of, the extrusion of the constituentmaterial through the nozzle.

In a still yet further embodiment, the additive manufacturing apparatusfurther includes a spatial orienting mechanism configured to spatiallyorient the channel to thereby control the aggregation of the firstcomponent material and the second component material.

In another embodiment, the additive manufacturing apparatus furtherincludes at least a second channel disposed proximate the first channeland configured to transmit the second component material, and a rotatingmechanism for translating the first channel and second channel in acircular path such that the respective component materials that outflowfrom the respective channels can be controllably intertwined to therebyform the constituent material.

In still another embodiment, the subassembly includes a shutter assemblyconfigured to control the dimensions of the cross-section of constituentmaterial that is extruded through the nozzle.

In a further embodiment, a method of fabricating an object includes:progressively depositing constituent material onto a surface to form theshape of the object to be fabricated in accordance with an additivemanufacturing process; and manipulating the material properties of atleast some portion of the constituent material that is deposited onto asurface such that at least some portion of the deposited constituentmaterial possesses different material properties than at least someother portion of the deposited constituent material; where manipulatingthe material properties of the at least some portion of the constituentmaterial begins prior to, or concurrently with, its deposition onto asurface.

In a still further embodiment, progressively depositing the constituentmaterial onto a surface includes extruding the constituent materialthrough a nozzle, and manipulating the material properties of the atleast some portion of the constituent material begins after the at leastsome portion of the constituent material is extruded through the nozzle.

In a yet further embodiment, manipulating the material properties of theat least some portion of the constituent material includes one of:subjecting the at least some portion of the constituent material toelectromagnetic waves; magnetizing the at least some portion of theconstituent material; subjecting the at least some portion of theconstituent material to a gas; vibrating the at least some portion ofthe constituent material; and heating the at least some portion of theconstituent material.

In a still yet further embodiment, manipulating the material propertiesof the at least some portion of the constituent material includessubjecting the at least some portion of the constituent material toelectromagnetic waves.

In another embodiment, subjecting the at least some portion of theconstituent material to electromagnetic waves includes using fiber opticcables to transmit the electromagnetic waves from a wave source to theat least some portion of the constituent material.

In still another embodiment, subjecting the at least some portion of theconstituent material to electromagnetic waves includes using optics tofocus the electromagnetic waves onto the at least some portion of theconstituent material.

In yet another embodiment, the method of fabricating an object furtherincludes manipulating the material properties of at least some portionof the constituent material that is deposited onto a surface in at leastanother way.

In still yet another embodiment, the constituent material includes atleast two component materials; and manipulating the material propertiesof the at least some portion of the constituent material includesmanipulating the composition of the cross-section of the constituentmaterial that is deposited onto a surface.

In a further embodiment, manipulating the composition of thecross-section of the constituent material that is deposited onto asurface includes varying the aggregation of a first component materialand at least a second component material.

In a still further embodiment, varying the aggregation of a firstcomponent material and at least a second component material includesintertwining the first component material and at least the secondcomponent material as the constituent material is being deposited onto asurface.

In a yet further embodiment, manipulating the material properties of theat least some portion of the constituent material includes varying thecross-section of the constituent material that is deposited.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1C illustrate the advantages, relative to the prior art, oftreating a material as it is extruded in an additive manufacturingprocess in accordance with embodiments of the invention.

FIG. 2 illustrates a method of additively manufacturing an object whereconstituent material is manipulated in the deposition process inaccordance with an embodiment of the invention.

FIGS. 3A-3C illustrate various treating methods that can be imposed onmaterials as they are extruded in an additive manufacturing process inaccordance with embodiments of the invention.

FIG. 4 illustrates an additive manufacturing apparatus that includes anassembly that is configured to manipulate the material properties of theconstituent material, and is configured such that it can maneuver aroundthe nozzle in accordance with an embodiment of the invention.

FIG. 5 illustrates an additive manufacturing apparatus including a polararray of subassemblies that include electromagnetic wave sources thatcan be used to manipulate the material properties of the constituentmaterial in accordance with an embodiment of the invention.

FIG. 6 illustrates using fiber optics to transmit electromagnetic wavesto treat a material as it is extruded in accordance with an embodimentof the invention.

FIG. 7 illustrates an additive manufacturing apparatus whereby focusingelements are used to focus electromagnetic waves onto a constituentmaterial as it is extruded in accordance with an embodiment of theinvention.

FIGS. 8A-8B illustrates an additive manufacturing apparatus includingmultiple subassemblies, each configured to treat the constituentmaterial in a unique way, in accordance with an embodiment of theinvention.

FIGS. 9A-9C illustrate a constituent material that includes two aspectsbeing uniformly subjected to a treatment that impacts each aspectdifferently in accordance with embodiments of the invention.

FIGS. 10A-100 illustrate a constituent material that includes twoaspects that define a C-shape being uniformly subjected to a treatmentthat impacts each aspect differently in accordance with embodiments ofthe invention

FIGS. 11A-11C illustrate implementing different treating methods tocustomize the material properties of an object to be fabricated inaccordance with embodiments of the invention.

FIG. 12 illustrates a vase that includes varying levels of translucencythat has been fabricated using additive manufacturing techniques inaccordance with an embodiment of the invention.

FIG. 13 illustrates a pair of glasses that includes constituent materialhaving varying material properties that has been fabricated usingadditive manufacturing techniques in accordance with an embodiment ofthe invention.

FIG. 14 illustrates rotating a pair of component materials as they areextruded from respective channels to form a constituent material inaccordance with embodiments of the invention.

FIGS. 15A-15B illustrate rotating three component materials that areextruded from three respective channels to form a constituent materialin accordance with embodiments of the invention.

FIGS. 16A-16B illustrate manipulating the extrusion of a first componentmaterial within a second component material to form a constituentmaterial in accordance with embodiments of the invention.

FIGS. 17A-17B illustrates controlling a shutter for manipulating theaperture of the nozzle as it deposits material in accordance with anembodiment of the invention.

FIGS. 18A-18F illustrate different cross-sections that can be obtainedby manipulating the nozzle aperture in accordance with embodiments ofthe invention.

DETAILED DESCRIPTION

Turning now to the drawings, systems and methods for implementingadditive manufacturing processes incorporating active deposition areillustrated. In many embodiments, a method of additively manufacturingan object includes manipulating the material properties of at least someportion of the constituent material that is deposited in accordance withan additive manufacturing process to form the object such that at leastsome portion of the deposited constituent material possesses differentmaterial properties than at least some other portion of the depositedconstituent material, where manipulation of the material properties ofthe at least some portion of the constituent material begins prior to,or concurrently with its deposition onto a surface. In numerousembodiments, the method includes beginning the manipulation of the atleast some portion of the constituent material after it has beenextruded through the nozzle of an additive manufacturing apparatus. Inseveral embodiments, electromagnetic waves are used to begin themanipulation of the at least some portion of the constituent material.In a number of embodiments, certain portions of the constituent materialare manipulated in one way and certain portions of the constituentmaterial are manipulated in another way. In many embodiments, thecomposition of the cross-section of the constituent material ismanipulated prior to the deposition of at least some portion of theconstituent material onto a surface. In many embodiments, theaggregation of two component materials to form the constituent materialis controlled such that the composition of portions of the constituentmaterial can be varied.

Since its inception, additive manufacturing, or ‘3D Printing’, hasgenerated much interest from manufacturing communities because of theseemingly unlimited potential that these fabrication techniques canoffer. For example, these techniques have been demonstrated to produceany of a variety of distinct and intricate geometries, with the onlyinput being the final shape of the object to be formed. In manyinstances, a 3D rendering of an object is provided electronically to a‘3D Printer’, which then fabricates the object. Many times, a 3D Printeris provided with a CAD File, a 3D Model, or instructions (e.g. viaG-code), and the 3D Printer thereby fabricates the object. Importantly,as can be inferred, these processing techniques can be used to avoidheritage manufacturing techniques that can be far more resourceintensive and inefficient. The relative simplicity and versatility ofthis process can pragmatically be used in any of a variety of scenariosincluding for example to allow for rapid prototyping and/or to fabricatecomponents that are highly customized for particular consumers. Forexample, shoes that are specifically adapted to fit a particularindividual can be additively manufactured. Indeed, U.S. ProvisionalPatent Application No. 61/861,376 discloses the manufacture ofcustomized medical devices and apparel using additive manufacturingtechniques; U.S. Provisional Patent Application No. 61/861,376 and itsprogeny are hereby incorporated by reference. It should also bementioned that the cost of 3D printers has recently noticeablydecreased, thereby making additive manufacturing processes an even moreviable fabrication methodology.

Given the demonstrated efficacy and versatility of additivemanufacturing processes, their potential continues to be explored. Forexample, while the operation of many current generation additivemanufacturing apparatuses is premised on the uniform deposition of amaterial in the shape of the desired object such that the materialproperties of the corresponding printed object are largely homogenousthroughout its structure, in many instances it may be desirable toadditively manufacture a multi-material object. Accordingly, additivemanufacturing apparatuses and techniques have recently been developedthat can selectively deposit any of a plurality of different materialsduring the buildup of a desired object such that the printed object canbe made up of a plurality of different materials. For example, Stratasysis a 3D Printing Company that develops 3D printers that can deposit anyof a plurality of materials during the buildup of a single printedobject, i.e. the printed object can be printed to include a plurality ofdistinct materials. For instance, the Objet Connex line of printersdeveloped by Stratasys is adept at such ‘multi-material printing.’Incidentally, Stratasys also boasts of its PolyJet Technology whichallows 3D printing resolutions as fine as 0.0006″ per layer of depositedmaterial to be achieved. PolyJet technology essentially involvesdepositing a plurality of drops of liquid photopolymer onto a buildtray, and instantly uniformly curing the deposited drops with UV light.

Nonetheless, even with these laudable achievements, the state of the artcan further benefit from an ability to exercise even greater control andcustomization during the build of an object in accordance with anadditive manufacturing process. Accordingly, in many embodiments of theinvention additive manufacturing processes are implemented whereby thematerial properties of the constituent material of an additivelymanufactured object are controllably manipulated while the material isbeing deposited. In the context of this application, the constituentmaterial can be understood to be the material that forms the additivelymanufactured object. Thus, material that is deposited in accordance withan additive manufacturing process can become the constituent material ofthe additively manufactured object. Hence, by controllably manipulatingthe material properties of the constituent material while it is beingdeposited, different portions of the additively manufactured object canbe made to possess different material properties and additivelymanufactured objects can thereby be highly customized. For example, inmany embodiments, the material properties of the constituent materialare controlled by altering the constitution of the constituent material.These processes are now discussed in greater detail below.

Methods for Implementing Active Deposition in Additive ManufacturingProcesses

In many embodiments, additive manufacturing processes that incorporateactive deposition techniques are implemented. Active deposition can beunderstood to regard actively controlling the material properties ofmaterial that is deposited in conjunction with an additive manufacturingprocess to build up an object such that different portions of theadditively manufactured structure can be made to possess differentmaterial properties. Such techniques can be extremely advantageousinsofar as they can allow the fabrication of highly customizedstructures, e.g. different portions of the structure can have tailoredmaterial properties. Additionally, active deposition techniques can alsoimpact the buildup of an object. For example, constituent material canbe treated as it is being deposited so that it rapidly becomessufficiently rigid such that the weight of an overhang portion will notdistort its geometry.

FIGS. 1A-1C depict some of the advantages that active depositiontechniques in accordance with embodiments of the invention can confer inrelation to prior art additive manufacturing methods. In particular,FIG. 1A depicts the operation of a conventional additive manufacturingapparatus 100 that includes a nozzle head 102 that is seen depositingconstituent material 104 to build up an object 106. FIG. 1B depicts anadditive manufacturing apparatus 110 in accordance with embodiments ofthe invention that includes a nozzle head 112 and an ultraviolet (UV)electromagnetic wave source 114 that is configured to treat materialthat is extruded through the nozzle head 112. The apparatus is seendepositing material 116 to build up an object 118. Note that the objectincludes a relatively larger overhang feature 119 than anything seenwith respect to FIG. 1A—the additive manufacture of this feature 119 ismade possible as the UV electromagnetic wave source 114 can rapidly curethe material 116 as it is being deposited, such that the depositedmaterial 116 is relatively more rigid so that its weight doesn't distortthe desired overhang geometry 119. Essentially, the constituent material116 is sensitive to UV electromagnetic wave exposure such that UVelectromagnetic waves initiate the rapid hardening of the constituentmaterial.

FIG. 1C depicts yet another advantage that can be realized with activedeposition techniques. In particular, FIG. 1C depicts an additivemanufacturing apparatus 120 in accordance with embodiments of theinvention that includes a nozzle head 122 and a magnetizing source 124.The apparatus 120 is seen depositing material 126 to build up an object128. Notably, the magnetizing source 124 can selectively impart magneticpolarities onto the additively manufactured object 128. In this way, thefabricated object can be highly customized, as it can be specificallydetermined which regions of the fabricated object are to possessmagnetic properties, and to what extent.

The above-described non-limiting examples illustrate some of theadvantages that the incorporation of active deposition in additivemanufacturing techniques can provide. In many embodiments, additivemanufacturing processes include active deposition that is characterizedby the selective treatment of certain of the constituent material thatis deposited. FIG. 2 illustrates a method of additively manufacturing anobject that includes selectively manipulating the material properties ofthe constituent material during its deposition in accordance withembodiments of the invention. In particular, the method 200 includesdepositing 202 constituent material onto a surface to form the shape ofan object to be fabricated in accordance with an additive manufacturingprocess. Constituent material can be deposited 202 in accordance withany of a variety of additive manufacturing processes. For example, inmany embodiments, constituent material is deposited 202 in accordancewith a fused deposition modeling additive manufacturing process. Fuseddeposition modeling essentially regards depositing constituent material,usually in the form of a plastic filament or a metallic wire, into theshape of the desired object. Typically, the constituent material isextruded through a nozzle and thereby deposited. In a number ofembodiments, constituent material is deposited 202 in accordance with alaser engineered net shaping (LENS) process. In LENS additivemanufacturing, a feedstock metallic powder is provided to a build headthat heats and deposits the feedstock metal into the shape of thestructure to be formed. In several embodiments, constituent material isdeposited in accordance with an electron beam freeform fabrication(EBF³) additive manufacturing process. EBF³ additive manufacturingprocesses are similar to LENS additive manufacturing processes, exceptthat the feedstock metal is in the form of wire, and an electron beam istypically used to heat the wire.

In numerous embodiments, material is deposited 202 in conjunction with a6-axis 3d printing additive manufacturing process. Whereas conventional3d printing processes typically employ a vertically oriented build headthat causes the downward deposition of constituent material, 6-axis 3dprinting processes employ a build head that has six degrees of freedomand can thereby cause the deposition of the constituent material in anyof a variety of directions. As can be appreciated, 6-axis 3d printingprocesses are more versatile than conventional additive manufacturingprocesses.

The method 200 further includes manipulating 204 the material propertiesof at least some portion of the constituent material that is depositedonto a surface such that at least some portion of the depositedconstituent material possesses different material properties than atleast some other portion of the deposited constituent material, wherethe manipulation begins prior to, or concurrently with, its depositiononto a surface. The material properties can be manipulated 204 in anysuitable way in accordance with embodiments of the invention. Forinstance, in some embodiments, as discussed above with respect to FIG.1C, the magnetic properties of the constituent material are manipulated;in this way, certain portions of the deposited constituent material canhave different magnetic properties relative to other portions of thedeposited constituent material. Accordingly, the magnetic properties ofthe additively manufactured object can vary throughout the geometry ofthe object, and the magnetic properties can thereby be highlycustomized. For example, a screwdriver having a magnetic tip portion canbe additively manufactured using the above described processes.

In a number of embodiments, manipulating 204 the material properties ofthe constituent material includes manipulating the cross section of theconstituent material (e.g. the cross section being judged as it isdeposited onto a surface) such that the deposited constituent materialin one portion of the additively manufactured object embodies adifferent cross section than another portion. In general, theconstituent material can be manipulated in any of a variety of ways inaccordance with embodiments of the invention—embodiments of theinvention are not limited to manipulating the magnetic properties or thecross section of the material.

Moreover, any of a variety of techniques can be used to manipulate thematerial in accordance with embodiments of the invention. FIGS. 3A-3Cdepict some examples of techniques that can be used to manipulate thematerials properties of the constituent material in accordance withembodiments of the invention. In particular, FIG. 3A depicts a portionof an additive manufacturing apparatus that includes a subassembly 304that subjects constituent material 306, as it is extruded through thenozzle 302 during the deposition process, with a vapor that initiates amaterial transformation of the constituent material 306 as it is beingdeposited. Note that although the constituent material is being treatedprior to its deposition onto the surface, the completion of anytransformation may not happen until after the constituent material hasbeen deposited. For example, the subassembly 304 might initiate arelatively slow reaction that does not complete until after theconstituent material 306 has been deposited. While FIG. 3A depictssubjecting the constituent material 306 with a vapor, any similarprocess can be implemented in accordance with embodiments of theinvention. For example, in some embodiments, a subassembly is configuredto coat the constituent material (e.g. with color) as it is beingdeposited. The coating of the constituent material as it is beingdeposited adds a thin layer of material to the periphery of theconstituent material and thereby alters the material properties of theconstituent material. With this technique, different portions of theadditively manufactured structure can be, for example, coloreddifferently during the deposition process.

FIG. 3B depicts a portion of an additive manufacturing apparatus thatincludes a subassembly 314 that is configured to vibrate constituentmaterial 316 as it is extruded through a nozzle 312. The vibration ofthe constituent material 316 can, for example, initiate work hardeningthat can alter the material properties of the constituent material 316.

Similarly, FIG. 3C depicts a portion of an additive manufacturingapparatus that includes a subassembly 324 that is configured to heatconstituent material 326 as it exits a nozzle head 322. The heating, forexample, can manipulate the material properties insofar as constituentmaterial that is heated can be annealed.

Importantly, as can be appreciated, any combination of theabove-described subassemblies can be incorporated to manipulate thematerial properties of the constituent material in accordance withembodiments of the invention. Indeed, more generally, any combination ofany of a variety subassemblies that can manipulate the materialproperties of the constituent material in any of a variety of ways canbe incorporated in accordance with embodiments of the invention. Forexample, in some embodiments, the deposited constituent material ismanipulated by a subassembly that imposes a heat treatment on theconstituent material, a subassembly that imposes an electromagnetictreatment on the constituent material, and/or a subassembly that imposesa magnetic treatment on the constituent material. In some embodiments, asingle subassembly is capable of manipulating the constituent materialin a plurality of ways. For example, in some embodiments, a singlesubassembly can impose a magnetic treatment, an electromagnetictreatment, and/or a heat treatment on the constituent material. Ingeneral, the constituent material can be manipulated in any number ofways in accordance with embodiments of the invention.

In a number of embodiments, additive manufacturing apparatuses that areconfigured to incorporate active deposition techniques includesubassemblies that can be moved relative to the deposited constituentmaterial. For example, in many embodiments, a subassembly can maneuveraround and about constituent material as it is extruded through anadditive manufacturing nozzle head. In this way, cylindrical portions ofthe extruded material, for example, do not have to be treated uniformly;instead, the subassembly can maneuver so as to treat only certainportions of the constituent material that is extruded onto a surface.FIG. 4 illustrates an additive manufacturing apparatus that includes asubassembly that can maneuver relative to constituent material that isextruded through a nozzle. In particular, the additive manufacturingapparatus includes a nozzle 402 and a subassembly 404 that can maneuverwith respect to constituent material 406 that is extruded through thenozzle 402. As can be appreciated, the subassembly 404 can manipulatethe properties of the constituent material 406 in any suitable way,including in any of the above-described ways, in accordance withembodiments of the invention. The illustration depicts that thesubassembly 404 can maneuver with sufficient precision such that onlycertain portions 408 (as opposed to an entire portion of the extrudedsection) of the constituent material 406 have been treated. Thus, onlythose treated portions will possess the transformed material properties.In essence, the material properties of the constituent material can becustom-tailored with even greater precision.

Accordingly, it can be seen how the incorporation of active depositiontechniques in accordance with embodiments of the invention can allow themanufacture of highly customized objects. While several techniques areshown for manipulating the material properties, it should be clear thatthe material can be manipulated in any suitable way in accordance withembodiments of the invention. In many embodiments, the manipulation ofmaterial properties is achieved by subjecting the constituent materialto electromagnetic waves that initiate the transformation of thematerial properties, and this is now discussed in greater detail below.

Using Electromagnetic Waves to Initiate the Transformation of MaterialProperties

In many embodiments, electromagnetic waves are used to initiate thetransformation of materials properties of portions of the constituentmaterial. For example, in numerous embodiments, either infrared rays orultraviolet rays are used to initiate the transformation of materialsproperties of a constituent material as it is extruded through thenozzle. Of course, the constituent material can be exposed to anysuitable electromagnetic waves that initiate the transformation of itsmaterial properties. As can be appreciated, the constituent materialthat is to be deposited must be sensitive to the particular appliedelectromagnetic wave, and the effect of the electromagnetic radiationexposure on the material properties should be known. For example, insome embodiments, the constituent material is exposed to electromagneticradiation of a particular wavelength that alters the mechanicalproperties of the constituent material. In several embodiments, exposureto electromagnetic radiation of a particular wavelength alters theopacity of the material. For example, the constituent material caninclude a pigment that is sensitive to the applied electromagneticradiation such that the opacity of the constituent material can betuned. Of course, the constituent material can be sensitive to theapplication of electromagnetic radiation in any of a variety of ways,and this sensitivity can be utilized to controllably tune the materialproperties in accordance with embodiments of the invention.

FIG. 5 illustrates an additive manufacturing apparatus that includessubassemblies that are configure to irradiate constituent material as itis extruded through a nozzle, and thereby alter the constituentmaterial, in accordance with embodiments of the invention. Inparticular, the additive manufacturing apparatus includes a plurality ofsubassemblies 504 that are symmetrically disposed about a nozzle 502;the plurality of subassemblies are configured to irradiate theconstituent material with electromagnetic waves of a particularwavelength as it is extruded through the nozzle 502, and therebyinitiate a material transformation. The symmetrical distribution of thesubassemblies 506 around the perimeter of the deposited constituentmaterial 506 allows selected portions of the deposited constituentmaterial to be irradiated. As can be appreciated, the constituentmaterial can be irradiated with electromagnetic waves of any suitablewavelength. For example, the constituent material can be irradiated withultraviolet waves, infrared waves, X-ray waves, microwaves, etc.

Although FIG. 5 depicts that the subassemblies 504 are coupled to thenozzle head 502 and each subassembly 504 includes a source ofelectromagnetic radiation, in many embodiments, the electromagnetic wavesource is decoupled from the nozzle head; instead, the electromagneticwaves are delivered to the constituent material using any of a varietyof suitable techniques. For example, in many embodiments, fiberopticcables are used to deliver electromagnetic waves to the constituentmaterial as it is extruded through the nozzle. FIG. 6 depicts anadditive manufacturing apparatus that utilizes fiber optic cables todeliver electromagnetic waves to the constituent material as it isextruded through the nozzle. In particular, the additive manufacturingapparatus includes a nozzle 602 and a subassembly 604 that is used toexpose the constituent material 606 that is extruded through the nozzleto electromagnetic radiation of a particular wavelength. Notably, thesubassembly includes fiber optic cables 608 that transmitelectromagnetic waves originating from a source (not shown) to thesubassembly 604. In this way, the source of electromagnetic radiation isdecoupled from the nozzle. Decoupling the electromagnetic radiationsource from the nozzle head can confer a variety of benefits. Forexample, by decoupling the EM source, the nozzle head thereby requiresless power to maneuver during the build up of an additively manufacturedstructure. This can yield substantial power savings. Moreover, bydecoupling the electromagnetic radiation source from the additivemanufacturing apparatus, a single electromagnetic radiation source cansource multiple additive manufacturing apparatuses. Note that the use offiber optics can allow the electromagnetic wave source to be separatedfrom the body of the additive manufacturing apparatus by any suitabledistance. For example, the electromagnetic wave source can be located inone part of a business complex, while the body of the additivemanufacturing apparatus can be located at a different part of thebusiness complex. While the use of fiber optics to transmitelectromagnetic radiation waves is illustrated, EM waves can betransmitted using any suitable mechanism in accordance with embodimentsof the invention. For example, in many embodiments, electromagneticwaves are transmitted over the air using any of a variety of focusingelements that direct the waves toward the constituent material as it isdeposited through the nozzle. FIG. 7 depicts an additive manufacturingapparatus whereby electromagnetic wave sources are decoupled from thenozzle head, and focusing elements are used to deliver electromagneticwaves from the electromagnetic wave sources to the constituent materialthat is extruded through the nozzle. In particular, the additivemanufacturing apparatus 700 includes infrared wavelength sources 704that are decoupled from the nozzle 702. The additive manufacturingapparatus 700 further includes focusing elements 708 that are configuredto project the infrared electromagnetic radiation waves to theconstituent material 706 that is extruded through the nozzle. As before,the decoupling of the nozzle from the electromagnetic wave source allowsthe nozzle 702 to be more nimble, and can allow the additivemanufacturing apparatus 700 to draw less power during operation.

While the above description has listed a variety of ways in which thematerial properties of a constituent material can be controllablymanipulated, in many embodiments, the materials properties of theconstituent material is varied in multiple ways as it is beingdeposited. Thus for example, in many embodiments, additive manufacturingapparatuses include a plurality of subassemblies, each of which beingable to controllably manipulate select portions of the constituentmaterial in a different way. For instance, in some embodiments, anadditive manufacturing apparatus includes a first subassembly that isconfigured to controllably expose a constituent material to infraredelectromagnetic radiation and thereby initiate a first materialtransformation, as well as a second subassembly that is configured tocontrollably expose the constituent material to ultravioletelectromagnetic radiation and thereby initiate a second, different,material transformation. Essentially, a first material property of theconstituent material can be a function of exposure to infraredradiation, and a second material property of the constituent materialcan be a function of exposure to ultraviolet radiation. In this way,multiple material properties of the constituent material can becontrollably tuned during the deposition process. In severalembodiments, an additive manufacturing apparatus includes a singlesubassembly that can controllably manipulate deposited constituentmaterial in each of a plurality of different ways. For instance, in someembodiments, an additive manufacturing apparatus includes a subassemblythat can controllably expose a constituent material to infraredelectromagnetic radiation to initiate a first material transformation,and can also controllably expose the constituent material to anultraviolet radiation to initiate a second material transformation. Ascan be appreciated, the exposure of the constituent material to infraredradiation and to ultraviolet radiation need not be simultaneous. While,the above discussion has focused on using electromagnetic radiation toinitiate material transformation, it should be clear that theconstituent material can be transformed using any suitable technique inaccordance with embodiments of the invention.

FIGS. 8A-8B illustrate an additive manufacturing apparatus that includesa plurality of subassemblies, each of which being configured tocontrollably tune a separate respective material property of theconstituent material. In particular, FIG. 8A illustrates an additivemanufacturing apparatus that includes a first subassembly 814 that isconfigured to apply a first technique to the constituent material, asecond subassembly 816 that is configured to apply a second technique tothe constituent material, and a third subassembly 818 configured toapply a third technique to the constituent material as it is extrudedthrough the nozzle head 802. FIG. 8B depicts that the constituentmaterial 806 includes aspects that are sensitive to the first technique821 such that the application of the first technique augments a firstmaterial property of the constituent material; aspects that aresensitive to the second technique 822 such that the application of thesecond technique augments a second material property of the constituentmaterial; and aspects that are sensitive to the third technique 823 suchthat the application of the third technique augments a third materialproperty of the constituent material. Accordingly, each of the threematerial properties of the constituent material can be controllablytuned using the techniques that can be applied with the respectivesubassemblies 814, 816, and 818. For instance, the aspects of theconstituent material 806 that are sensitive to the first technique 821can be a pigment, the transparency of which is altered based on infraredradiation exposure; the aspects of the constituent material 806 that aresensitive to the second technique 822 can be a material that hardens asa function of exposure to ultraviolet radiation; and the aspects of theconstituent material 806 that are sensitive to the third technique canbe a material that magnetizes as a function of exposure to an appliedmagnetic field. Correspondingly, the first technique can compriseexposing the constituent material 806 to infrared radiation, the secondtechnique can comprise exposing the constituent material 806 toultraviolet radiation, and the third technique can comprise exposing theconstituent material 806 to a magnetic field. In general, embodiments ofthe invention include constituent materials that comprise a plurality ofaspects that are each differently sensitive to any of a variety ofapplied techniques, e.g. including, but not limited to, any of theabove-described techniques. Thus, for example a single feedstockconstituent material including a plurality of such aspects can be fedinto a respective additive manufacturing apparatus, and be imbued withdifferent, but customized, material properties during the buildup of adesired object. Of course, it should be appreciated that the constituentmaterial can include any number of aspects that are differentlysensitive to applied techniques; embodiments of the invention are notrestricted to constituent materials having exactly three such aspects.It should also be appreciated that although FIGS. 8A-8B depict threesubassemblies that each treat a respective aspect of the constituentmaterial, in some embodiments, a single subassembly can apply differenttechniques to treat the individual aspects of the constituent material.

In many embodiments, a constituent material includes a plurality ofaspects such that when the constituent material is uniformly subjectedto a single treatment, at least two of the plurality of aspects of theconstituent material respond differently to the treatment such that eachof the at least two of the plurality of aspects develop differentmaterial properties. FIGS. 9A-9C depict a constituent material thatcomprises a plurality of different aspects, such that when theconstituent material is subjected to a particular uniform treatment,each of the aspects respond differently such that they each developdifferent material properties. In particular, FIG. 9A depicts the crosssection of a constituent material 906 that includes two aspects 921 and922. FIG. 9A depicts that the constituent material 906 is being exposedto a treatment 916 that uniformly applied to its cross section. FIG. 9Bdepicts that the uniform treatment 916 has acted to eliminate theportion of the constituent material that was defined by the presence ofthe first aspect 921, and transmute the material properties of thesecond aspect 922. Of course, the uniform treatment 916 can impact theconstituent material 906 in any of a variety of ways in accordance withembodiments of the invention. Thus, for example, FIG. 9C depicts thatthe uniform treatment 916 has acted to transmute the material propertiesof each of the aspects 921 and 922 in a different way.

Although FIG. 9 depicts aspects that are cylindrical in nature, itshould be clear that the aspects within the constituent material can beof any suitable shape in accordance with embodiments of the invention.Indeed, as will be discussed later, the cross section of the constituentmaterial can be of any suitable shape in accordance with embodiments ofthe invention. Thus, for example, FIGS. 10A-10C depict a constituentmaterial that includes aspects defining a C-shape. FIGS. 10A-10C aresimilar to the illustrations seen in FIGS. 9A-9C, except that theconstituent material 1006, includes first and second aspects 1021, 1022that define a C-shape; as before, a uniform treatment 1016 is applied tothe constituent material 1006.

Fabrication Strategies Incorporating Active Deposition

In many embodiments, additive manufacturing processes incorporate activedeposition techniques are used to fabricate structures that includevaried material properties. For example, as alluded to above, aconstituent material may be sensitive to particular wavelengths ofelectromagnetic radiation insofar as the electromagnetic radiationexposure can controllably tune the constituent material's mechanicalproperties.

FIGS. 11A-11C depict how active deposition techniques can be used todictate the mechanical properties of an additively manufacturedstructure. In particular, FIG. 11A illustrates that when a constituentmaterial 1106 is exposed to infrared radiation from an infraredradiation source 1114, the resulting structure 1108 has demonstrablepliability. FIG. 11B illustrates that when the constituent material 1106is exposed to ultraviolet radiation from an ultraviolet radiation source1116, the resulting structure 1128, has demonstrable rigidity. Inessence, exposure to infrared radiation causes the constituent material1106 to develop pliability, while exposure to ultraviolet radiationcauses the constituent material to develop rigidity. Accordingly, thesemechanical properties of the constituent material 1106 may becontrollably tuned while the constituent material 1106 is beingdeposited.

Thus, FIG. 11C illustrates that the constituent material 1106 of thebase of the additively manufactured structure 1138 has been treated withultraviolet radiation from an ultraviolet radiation source 1116, whilethe upper portion of the additively manufactured structure 1138 has beentreated with infrared radiation from an infrared radiation source 1114.Accordingly, the base of the additively manufactured structure 1138 isdeveloped to have notable structural rigidity, whereas the upper portionof the additively manufactured structure 1138 is developed to havenotable pliability.

Of course, while the tuning of the mechanical properties has beendiscussed and illustrated, it should be clear that any of theconstituent material properties can be modified in accordance withembodiments of the invention using any of a variety of treatments. Forexample, FIG. 12 depicts an additively manufactured vase having variedtranslucence in accordance with embodiments of the invention. Inparticular, it is illustrated that the vase 1200 is transparent in itsupper portion 1202, semi-transparent in its middle portion 1206, and nottransparent at its base 1208. The vase 1200 was fabricated from aconstituent material that included a pigment that is sensitive toinfrared radiation such that the transparency of the constituentmaterial is a function of its exposure to infrared radiation. Thus,during the additive manufacture of the vase, the different levels wereexposed to different levels of infrared radiation to controllablydetermine the level of transparency, e.g. where greater transparency wasdesired, the constituent material was subjected less infrared radiationand vice versa.

For example, FIG. 13 depicts a pair of glasses that can be fabricatedusing additive manufacturing processes that incorporate activedeposition in accordance with embodiments of the invention. Inparticular, the pair of glasses 1300 defines three portions: theskeleton of the frame 1304, the surface of the frame 1306, and thelenses 1308. The constituent material is sensitive to ultravioletradiation as well as infrared radiation. In particular, exposure toultraviolet radiation causes the constituent material to develophardness while exposure to infrared radiation causes the material tolose its translucency. Thus, when constituent material was deposited toform the portions of the surface of the frame 1304, the constituentmaterial was subjected to infrared radiation and not subjected to UVradiation so that the surface of the frame 1304 became soft andnon-transparent. Conversely, when constituent material was deposited toform the lens, the constituent material was treated with 100% UVradiation and 0% infrared radiation so that the deposited constituentmaterial became hard and transparent. When constituent material isdeposited to form the skeleton of the frame 1302, the constituentmaterial was treated with UV radiation at 100% so that the skeleton ofthe frame 1302 is developed to be hard. The translucency of the skeletonof the frame 1302 does not impact the operation of the glasses, so itcan be exposed to any level of infrared radiation. While severalexamples of structure having varied material properties are illustrated,it should be emphasized that examples discussed are meant to beillustrative and not exhaustive. Any of a variety of material propertiescan be tuned during the deposition of the constituent material in anadditive manufacturing process in accordance with embodiments of theinvention. More generally, it should be understood that theabove-mentioned concepts are meant to be versatile; thus, for example,any combination and any permutation of the above-described techniquescan be implemented in accordance with embodiments of the invention. Theabove-described concepts are meant to be illustrative and notexhaustive. Additionally, it should also be appreciated that while theabove-descriptions have regarded additive manufacturing apparatuses thatinclude subassemblies that work in conjunction with the nozzle head, inmany embodiments, the subassemblies can operate independently of thenozzle-head. For example, the subassemblies can be controlled to treatalready deposited constituent material. The subassemblies may be used inthis manner to refine the material properties of already depositedconstituent material in accordance with embodiments of the invention.

While the above illustrations and discussions have suggested thetransformation of the bulk inherent material properties of theconstituent material, in many embodiments, the material properties aremanipulated insofar as the cross-section of the extruded constituentmaterial is manipulated. These aspects are now discussed in greaterdetail below.

Manipulating the Cross-Section of the Deposited Constituent Material

In many embodiments, the constituent material is manipulated insofar asits cross section as it is being deposited onto a surface in accordancewith a deposition process is manipulated. The cross section of thematerial can be manipulated in any suitable way in accordance withembodiments of the invention. For example, the deposited constituentmaterial can include a first component material and a second componentmaterial that are intertwined while the aggregate constituent materialis being deposited.

FIG. 14 depicts that a constituent material 1406 is manipulated byintertwining a first component material 1412 with a second componentmaterial 1414 while the constituent material 1406 is being deposited inaccordance with embodiments of the invention. Although a constituentmaterial 1406 having two component materials 1412, 1414 is depicted, itshould be clear that a constituent material having any number ofcomponent materials can be deposited in accordance with embodiments ofthe invention. For example, FIGS. 15A-15B depict that a constituentmaterial is manipulated by intertwining first, second, and thirdcomponent materials while the constituent material is being deposited.The constituent material can be an aggregate of any number of componentmaterials in accordance with embodiments of the invention.

The cross section of the deposited constituent material can be alteredin any suitable way in accordance with embodiments of the invention, andis not just limited to intertwining component materials. For example, insome embodiments, the first component material is enveloped by thesecond component material. In many embodiments, the spatial relationshipbetween a first component material and a second component material canbe controllably varied in any suitable way. FIGS. 16A-16B depict how aconstituent material includes a first component material disposed withina second component material, where the location of the first componentmaterial within the second component material can be controllablyvaried. In particular, FIG. 16A depicts that the first component 1612material defines a spiraling path within a second component material1614. This can be achieved for example by rotating the first componentmaterial 1612 within the second component material 1614 in a circularpath while the aggregate is being deposited onto a surface. Acontrollable channel can be used to cause this outcome. For example,FIG. 16B depicts a controllable channel 1630 that emits the firstcomponent material 1612 within the second component material 1614. Therelative location of the channel 1630 within the second componentmaterial 1614 can be controlled that the emission of the first componentmaterial within the second component material can be controlled; in thisway the constitution of the cross section of the constituent materialcan be controlled.

These techniques can be advantageous in the additive manufacture of anyof a variety of structures in accordance with embodiments of theinvention. For example, in some embodiments, a wire is additivelymanufactured whereby the first component material is conductive, and thesecond conductive material is insulating. Accordingly, the cross sectionof the constituent material defines the cross section of the wire; whereit is desired that the wire include an exposed lead, the channelresponsible for emitting the conductive first component material can becontrolled to move to the periphery for the constituent material suchthat the first conductive component material is exposed. Of course, itshould be understood that the above described techniques are not limitedto the fabrication of wires; indeed, in many embodiments, thesetechniques are used to fabricate any of a variety of structures.

The cross section of the constituent material can be transformed in anysuitable way in accordance with embodiments of the invention, and is notlimited to varying the spatial relationship of component materialswithin the constituent material. For example, as alluded to above, insome embodiments, the deposited constituent material is coated with acolored material prior to deposition—in this way, the cross section ofthe constituent material is being manipulated insofar as a thin layer ofcolored coating is being applied to the constituent material. Indeed,the cross section of the component material can be modified in anysuitable way in accordance with embodiments of the invention. In anumber of embodiments, the geometry of the cross section is transformed,and this aspect is now discussed below in further detail.

Manipulating the Geometry of the Cross Section of the ConstituentMaterial in Accordance with Embodiments of the Invention

In many embodiments, the geometry of the cross section of theconstituent material is controllably manipulated during the depositionprocess. The geometry can be varied in any number of ways using any of avariety of techniques. For example, in some embodiments, a shuttermechanism is adjoined to the nozzle to vary the geometry of the extrudedconstituent material; the shutter mechanism can controllably manipulatethe geometry of the extruded constituent material. FIGS. 17A-17B depictthe operation of a shutter assembly in accordance with embodiments ofthe invention. In particular, FIG. 17A depicts that the shutter assembly1720 is adjoined to the nozzle 1702 and is in a first non-activatedposition, where the constituent material 1706 is extruded into a basegeometry, while FIG. 17B depicts that the shutter assembly 1720 is in anactivated position, where the geometry of the cross section is in asecond controlled position. Accordingly, any of a variety of crosssections can be defined. For example, FIGS. 18A-18F depict a number ofcross sections of deposited constituent material that can be definedusing shutter assemblies in accordance with embodiments of theinvention. In particular: FIG. 18A depicts that a square cross sectioncan be defined; FIG. 18B depicts that an augmented triangular crosssection can be defined; FIG. 18C depicts that a six-pointed star can bedefined; FIG. 18D depicts that a triangular cross section can bedefined; FIG. 18E depicts that a trapezoid can be defined; and FIG. 18Fdepicts that a circular cross section can be defined. While severalillustrative cross sections are illustrated and discussed, it should beclear that any of a variety of cross section geometries can beimplemented in accordance with embodiments of the invention.

While the above discussion has regarded manipulating the cross-sectionof the deposited constituent material prior to extrusion, theconstituent material can be manipulated prior to extrusion using any ofa variety of methods in accordance with embodiments of the invention.For example, in some embodiments, the nozzle head is fabricated from amaterial that is transparent to certain electromagnetic wavelengths,e.g. infrared radiation; simultaneously, the constituent material may besensitive to infrared radiation exposure. Thus, prior to extruding theconstituent material, the nozzle head may be exposed to infraredradiation; because it is transparent to infrared radiation, the materialproperties of the constituent material that is within the nozzle headcan be transmuted by the infrared radiation exposure. In this way, theinitiation of the transformation of the material properties of theconstituent material can begin prior to the extrusion. Of course, itshould be appreciated that although the above example is discussed inconnection with infrared radiation, any suitable electromagneticwavelength range may be implemented. More generally, while severalexamples of manipulating the material properties of constituent materialare given, it should be understood that the material properties of aconstituent material can be manipulated prior to extrusion in anysuitable way in accordance with embodiments of the invention. Thediscussed examples are meant to be illustrative and not exhaustive.

In general, as can be inferred from the above discussion, theabove-mentioned concepts can be implemented in a variety of arrangementsin accordance with embodiments of the invention. Accordingly, althoughthe present invention has been described in certain specific aspects,many additional modifications and variations would be apparent to thoseskilled in the art. It is therefore to be understood that the presentinvention may be practiced otherwise than specifically described. Thus,embodiments of the present invention should be considered in allrespects as illustrative and not restrictive.

What is claimed is:
 1. An additive manufacturing apparatus comprising: anozzle configured to accommodate the extrusion of a constituent materialthrough the nozzle and deposit the constituent material onto a surfacein accordance with an additive manufacturing process to build up anobject to be fabricated; and at least one subassembly configured tomanipulate the material properties of at least some portion of theconstituent material such that different portions of the depositedconstituent material can be made to possess different materialproperties; wherein the at least one subassembly is configured to beginthe manipulation of the material properties of the at least some portionof the constituent material prior to, or concurrently with, itsdeposition onto a surface.
 2. The additive manufacturing apparatus ofclaim 1, wherein the subassembly is configured to begin the manipulationof the material properties of the at least some portion of theconstituent material after it is extruded through the nozzle.
 3. Theadditive manufacturing apparatus of claim 2, wherein the subassemblycomprises at least one of: an electromagnetic wave source configured tosubject at least some portion of the constituent material toelectromagnetic waves to begin the manipulation of its materialproperties; a magnetizing source configured to begin the magnetizationof the at least some portion of the constituent material; a source ofgas configured to subject the at least some portion of the constituentmaterial to the gas that begins the manipulation of its materialproperties; a vibrating apparatus configured to vibrate the at leastsome portion of the constituent material to thereby begin themanipulation of its material properties; and a heating source configuredto heat the at least some portion of the constituent material to therebybegin the manipulation of its material properties.
 4. The additivemanufacturing apparatus of claim 3 further comprising aspatial-orientation mechanism configured to orient the subassemblyrelative to the nozzle.
 5. The additive manufacturing apparatus of claim3, wherein the subassembly comprises at least one electromagnetic wavesource.
 6. The additive manufacturing apparatus of claim 5 wherein theelectromagnetic wave source is coupled to the nozzle.
 7. The additivemanufacturing apparatus of claim 5, wherein the electromagnetic wavesource is independent of the nozzle, such that the nozzle can moveindependently of the electromagnetic wave source during the buildup ofan object to be fabricated.
 8. The additive manufacturing apparatus ofclaim 7, wherein the subassembly further comprises fiber optic cablesconfigured to transmit electromagnetic waves generated by theelectromagnetic wave source to constituent material that is extrudedthrough the nozzle.
 9. The additive manufacturing apparatus of claim 7,wherein the subassembly further comprises optics for focusingelectromagnetic waves generated by the electromagnetic wave source ontoconstituent material that is extruded through the nozzle.
 10. Theadditive manufacturing apparatus of claim 2, wherein the at least onesubassembly is at least two subassemblies.
 11. The additivemanufacturing apparatus of claim 10, wherein: the at least twosubassemblies are disposed about the perimeter of the nozzle; and eachof the at least two subassemblies is configured to begin themanipulation of the material properties in the same manner on differentrespective portions of constituent material that is extruded through thenozzle.
 12. The additive manufacturing apparatus of claim 10, whereineach of the subassemblies is configured to begin the manipulation of thematerial properties on constituent material that is extruded through thenozzle in a manner differently than the other respective subassembly.13. The additive manufacturing apparatus of claim 1, wherein: the nozzleis configured to accommodate the extrusion of a constituent materialthat comprises at least two component materials; and the subassembly isconfigured to begin the manipulation of the material properties of atleast some portion of the constituent material by manipulating thecomposition of the cross-section of the constituent material as it isextruded through the nozzle.
 14. The additive manufacturing apparatus ofclaim 13, wherein the subassembly is configured to manipulate thespatial positioning of a first component material relative to a secondcomponent material within a given cross-section of the constituentmaterial as it is deposited on a surface.
 15. The additive manufacturingapparatus of claim 14, wherein the subassembly comprises a channel thatis configured to transmit the first component material for aggregationwith the second component material to form the constituent material. 16.The additive manufacturing apparatus of claim 15, wherein thesubassembly is configured to cause the aggregation of the firstcomponent material and the second component material prior to, or at thetime of, the extrusion of the constituent material through the nozzle.17. The additive manufacturing apparatus of claim 15, further comprisinga spatial orienting mechanism configured to spatially orient the channelto thereby control the aggregation of the first component material andthe second component material.
 18. The additive manufacturing apparatusof claim 15, further comprising at least a second channel disposedproximate the first channel and configured to transmit the secondcomponent material, and a rotating mechanism for translating the firstchannel and second channel in a circular path such that the respectivecomponent materials that outflow from the respective channels can becontrollably intertwined to thereby form the constituent material. 19.The additive manufacturing apparatus of claim 1, wherein the subassemblycomprises a shutter assembly configured to control the dimensions of thecross-section of constituent material that is extruded through thenozzle.